Infill material for synthetic turfs and synthetic turfs so obtained

ABSTRACT

Synthetic turf (1) comprising a mat (2) equipped with a first face (2a), which in use is arranged next to a surface (50) to coat, and with a second face (2b) opposite to the first face (2a). The synthetic turf (1) comprises, furthermore, a plurality of filaments (3) knitted to the mat (2) and made of a synthetic material. Above the second face (2b) of the mat (2), furthermore, an infill material (10) is present that is arranged all around the filaments (3) of artificial material. The infill material (10) comprises, in particular at least one layer (15) consisting of a mixture of a predetermined amount of cereal husks, such as rice husks, husks of wheat, husks of rye, husks of oat, husks of spelt, or a combination thereof, and wood sawdust obtained by a raw material with high content of lignin, such as Teak sawdust, Mahogany sawdust, Iroko sawdust, or a combination thereof.

FIELD OF THE INVENTION

The present invention relates to an infill material for a synthetic turf comprising organic material of vegetable origin, and it also relates to synthetic turfs so obtained.

BACKGROUND OF THE INVENTION

As well known, an artificial turf is essentially a mat of plastic material to which blades of synthetic material are connected in order to simulate a natural turf. The blades of synthetic material are knitted to the mat by means of known processes, in order to provide a warp of filaments, thick according to the needs. All around the blades of synthetic material an infill material is usually distributed, simply called infill, for example a layer of sand followed by a layer of granular synthetic or natural material.

According to the kind of sports and of the use to which the synthetic turf is destined, a suitable type of infill material is chosen (see for example Italian patent applications No. PI2001A000049 and No. PI2003A000036, in the name of the same applicant).

In particular, the infill material provides a draining action by adjusting the drainage of rainwater or of irrigation water; a protection of the mat; a high duration to the artificial turf; and especially gives to the turf mechanical, physic and technologic qualities typical of natural turfs.

Such qualities are, for example: the elasticity of the ground for the user, the rebound of the ball or other piece of equipment, capacity of absorption of the hits when falling down, tensile and torque resistance to the force caused by the shoe, resistance against compression and against penetration of external bodies, as well as capacity of absorption and drainage of water in case of rainfalls and irrigation.

For these reasons, the infill material of known type comprises a predetermined amount of sand, which is necessary for an effective drainage of the synthetic turf, and a predetermined amount of rubber material, usually granular, which gives to the synthetic turf the necessary physical and mechanical characteristics as above described, and, in particular, a high elasticity.

However, the rubber infill material used as above described is obtained mainly from waste material, such as ground spent tires, or in any case from a mixture of elastomers, and therefore it has a high content of toxic substances and potentially noxious both for the environment and for the people, such as heavy metals and solvents of various type.

Alternatively, granules of freshly prepared rubber are used in various chemical compositions, which are more expensive and in any case are difficult to dispose of at the end of the life of the turf in addition to a high cost.

The presence of such noxious substances in the rubber used as infill material represents, furthermore, an obstacle to dismantling spent synthetic turfs to be changed by a new synthetic turf.

Furthermore, the elastomeric material cannot retain much water and accumulate heat, such that in the hot seasons they create much more discomfort to the players than natural turfs.

JP2003034906 describes a synthetic turf comprising a support to which the artificial fibers are connected. Al around the artificial fibers an infill material is present. The infill comprises a lower layer consisting of rubber granules, in particular ground spent tires, and at least one upper layer of loose material. The loose material can be for example “chaff”, sawdust, or other material having a light color, in such a way that it can reflect the sun light and avoid, then, an excessive heating of the turf. is, therefore, necessary that the layer of granular material makes up the upper part of the infill material, i.e. the layer that is arranged above the layer of ground spent tires. This is obtained using a granular material having a specific weight set between 0.3 and 1.

However, also the turf described in JP2003034906 has the drawbacks, above described, of fields involving waste material, such as ground spent tires, or a mixture of synthetic elastomers.

Another drawback of the solution described in JP2003034906 is that the upper layer, since it is very light, can be easily blown away by the wind. During a sports match this could hamper the players action, since it is not possible during the match to keep wet the upper layer.

In EP0541844 a artificial soil is described that can be used as growth substrate for cultivation of plants, for example, in golf courses. The artificial soil is highly resistant to vermin and virus and allows then reducing the use of pesticides and chemical products, which are commonly used in the cultivations made in natural soils. More in detail, the artificial soil comprises a layer of gravel, a layer of sand, and a layer consisting of an artificial soil for cultivation of plants. The artificial soil comprises a ground of cultivation for mushrooms in a ratio set between 60% and 80% by weight, in addition to a plurality of components among which sand, coal, mineral ore and chaff.

In the document no reference is made to the use of the artificial soil for making synthetic turfs.

SUMMARY OF THE INVENTION

It is therefore a feature of the present invention to provide an infill material for synthetic turfs that has not, or presents in an limited amount, rubber granules, and has in any case a high elasticity.

It is another feature of the present invention to provide an infill material for synthetic turfs that is much more biodegradable with time and more easily disposed of with respect to the infill presently known, containing large percentage of rubber granules.

It is a further feature of the present invention to provide an infill material for synthetic turfs that is made up, prevailingly, or completely, of natural vegetable material and is at the same time imputrescible and then not attackable by bacteria.

It is a particular feature of the present invention to provide an infill material for synthetic turfs that is non-flammable.

It is, furthermore, a feature of the present invention to provide an infill material for synthetic turfs that has a low retention of water and then capable of adjusting normal outflow of water through the synthetic turf.

It is a further feature of the present invention to provide an infill material for synthetic turfs that avoids the risk for light components to be blown away by the wind, and then to avoid hampering players during sports matches.

It is a further feature of the present invention to provide an infill material for synthetic turfs that presents a high elasticity and then achieves a technical quality comparable and even higher than a synthetic infill which uses the rubber as infill material.

These and other features are accomplished with one exemplary infill material, according to the invention, for synthetic turfs whose main feature is that it comprises a mixture of:

-   -   a measured amount of a defibrated arboreus material which is         resistant to microbial digestion;     -   a measured amount of cereal husks.

Advantageously, the defibrated arboreus material which is resistant to microbial digestion is a loose final product from raw material based on coconut coir.

Alternatively, the defibrated arboreus material which is resistant to microbial digestion is obtained by sawdust wood obtained by a raw material with high content of lignin, in particular selected from the group comprised of:

-   -   Teak sawdust;     -   Mahogany sawdust;     -   Iroko sawdust;     -   or a combination thereof.

In particular, the defibrated arboreus material which is resistant to microbial digestion, for example coir, in the presence of moisture creates a three-dimensional reticular structure that holds the lighter parts such as the cereal husks “trapping them” and avoiding that they can get free from the turf infill and scatter in the environment. This makes it possible to exploit fully the physical characteristics of the cereal husks, in particular its high elasticity, and to avoid at the same time that it can hamper players during sports matches. Furthermore, the cereal husks have a shell-like shape, which gives to the mixture a high void ratio.

The cereal husks, or chaff, is a by-product of cereals work and is formed by the bracts, or glumelle, which encircle the raw kernel after the threshing.

In particular, the cereal husks can be selected from the group comprised of:

-   -   rice husks;     -   husks of wheat;     -   husks of rye;     -   husks of oat;     -   husks of spelt;     -   or a combination thereof.

Preferably, the cereal husks comprise rice husks, which have a high rate of elasticity against bending of the hulls. In particular, the cereal husks substantially lens-shaped comprising concave portions and convex portions with rather high concavity. For these particular morphological features the cereal husks, and, in particular, the rice husks, occupy a high volume, but have a high void ratio. Thus, on the one hand a high elasticity is achieved and on the other hand a high draining action is achieved by the mixture that contains them.

In particular, the cereal husks can be present in said mixture in a percent volume set between 1% and 15%.

Advantageously, the cereal husks present in said mixture in a percent volume set between 1% and 10%. For example, the percent volume of the cereal husks with respect to the overall volume of the mixture can be about the 6%.

In particular, the matrix consisting of the defibrated arboreus material which is resistant to microbial digestion is capable of keep a limited amount of cereal husks. More precisely, cereal husks higher than the 15-20% v/v are not held by the matrix with the above described drawbacks.

Advantageously, said mixture comprises, furthermore, a predetermined amount of a loose final product obtained from raw material based on ground cork. This way, mixing the ground cork to the cereal husks and to the defibrated arboreus material which is resistant to microbial digestion, the physical characteristics of the infill material are further improved. In particular, the presence of the cork increases further the elasticity of the synthetic turf and then of improving the athletes performances.

Advantageously, the infill material comprises, furthermore, a predetermined amount of sand.

For example, said mixture can comprise a predetermined amount of sand.

In an exemplary embodiment of the invention the infill material can comprise:

-   -   a lower layer of sand, in particular, said layer of sand have a         volume set between 5% and 60% with respect to the total volume         of said infill material;     -   an upper layer consisting of said mixture.

In particular, the layer of sand can be present in a volume set between 8% and 30% with respect to the total volume of the infill material.

In particular, the sand has a granulometry set between 0.4 mm and 2.0 mm.

In particular, the defibrated arboreus material which is resistant to microbial digestion is present in said mixture in a percent volume set between 40% and 95%, Advantageously between the 65% and 85% v/v.

In particular, the measured amount v/v of the cork present in the mixture of loose material of vegetable natural origin is set between 15% and 40% v/v, Advantageously, set between 20% and 35% v/v.

Advantageously, the mixture of loose material of vegetable natural origin has the following composition:

-   -   between about 1% to about 15%, in particular between 1% and 10%,         v/v of cereal husks, in particular rice husks;     -   between about 20% and about 35%, in particular between about 20%         and about 25%, v/v of cork, in particular of ground cork;     -   between about 55% and 80%, in particular between about 65% and         about 75%, of defibrated arboreus material which is resistant to         microbial digestion, in particular loose material based on         coconut coir.

Preferably, the cereal husks have a moisture content set between 5% and 15%.

In particular, the loose final product from raw material based on coconut ground comprises the sole granular and fibrous part contained in the starting raw material based on coconut. For example, the granular and fibrous part can be obtained putting the raw material starting through a separation step of the granular and fibrous part from the powder in it present.

Advantageously, the granular and fibrous part contained in the starting loose product is separated by sieving the raw material based on coconut coir.

Preferably, the granular and fibrous part of coconut ground has a grain size larger than 500 micron (μm) for 90% by weight.

Advantageously, the sieving of the loose material is carried out by a sieving means selected from the group comprised of:

-   -   a mechanical sieve, in particular a rotating sieve, a vibrating         sieve, etc.     -   an electromagnetic sieve.

Advantageously, the granular and fibrous part has the following grain size:

-   -   among 20% and 40% by weight set between 0.8 mm and 1.25 mm;     -   among 15% and 35% by weight set between 1.25 mm and 1.60 mm;     -   among 50% and 70% by weight larger than 1.6 mm.

According to another aspect of the invention, a synthetic turf for sports or recreational activities comprises:

-   -   a mat equipped with a first face that is adapted to be arranged         on a surface to coat and with a second face opposite to the         first face;     -   a plurality of filaments of synthetic material knitted on said         mat, said plurality of filaments of synthetic material         protruding from said second side in order to form a turf;     -   an infill material for said turf, said infill material         comprising a loose material of vegetable origin, said loose         material of vegetable origin being a mixture of:     -   a measured amount of a defibrated arboreus material which is         resistant to microbial digestion;     -   a measured amount of cereal husks.

Advantageously, the filaments of synthetic material knitted on said mat comprises:

-   -   a first group of longer filaments, said first group of filaments         protruding from said infill material;     -   a second group of shorter filaments, said second group of         filaments arranged within the infill material without protruding         from it, or protruding minimally from it, for example of 2-5 mm.

In particular, the filaments of the first group of filaments protrude from the infill material about 10-15 mm.

The second group of filaments may have twisted shape in order to give higher support to the infill material.

According to a further aspect of the invention, a method for making a synthetic turf comprises the steps of:

-   -   preparing a turf comprising a mat to which a plurality of         filaments of synthetic material is connected, said mat equipped         with a first face that is adapted to be arranged on a surface to         coat and with a second face opposite to the first face, said         plurality of filaments of synthetic material protruding from         said second face;     -   laying on said first face of said mat an infill material         obtaining a synthetic turf, said infill material comprising a         loose material of vegetable origin, said loose material of         vegetable origin being a mixture of:         -   a measured amount of a defibrated arboreus material which is             resistant to microbial digestion;         -   a measured amount of cereal husks.

In particular, the step of distributing said infill material comprising the steps of:

-   -   distributing a layer of sand on said mat;     -   distributing a layer consisting of said mixture on said layer of         sand.

Advantageously, the layer of sand has a volume set between 5% and 55% with respect to the total volume of said infill material.

In an exemplary embodiment, the infill material can comprise, furthermore, a predetermined amount of sand mixed to the rice husks and/or to the cork and/or to the coconut coir.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be made clearer with the following description of an exemplary embodiment thereof, exemplifying but not limitative, with reference to the attached drawings in which:

FIG. 1 diagrammatically shows a cross sectional view of a first exemplary embodiment of an infill material for synthetic turfs, according to the invention;

figures from 2 to 4 show diagrammatically transversal cross sections of some exemplary embodiments of the infill material for synthetic turfs of FIG. 1.

DESCRIPTION OF SOME PREFERRED EXEMPLARY EMBODIMENTS

With reference to FIG. 1, a synthetic turf 1, according to the invention, comprises a mat 2 equipped with a face 2 a, which in use is arranged next to a surface 50 to coat, and a face 2 b opposite to face 2 a. The synthetic turf 1 comprises, furthermore, a plurality of filaments 3 knitted to mat 2 and made of a synthetic material. Furthermore, above face 2 b of mat 2, an infill material 10 is present all around the filaments 3 of artificial material.

According to the invention and as shown in FIG. 1, the infill material 10 comprises at least one layer 15 consisting of a mixture of at least one measured amount of a defibrated arboreus material which is resistant to microbial digestion and of a predetermined amount of cereal husks. For example, the cereal husks can be rice husks, husks of wheat, husks of rye, husks of oat, husks of spelt, or a combination thereof. In particular, the husks comprise a by-product deriving from cereal transformation and is the set of the bracts, or hulls, which enclose the kernel. More precisely, in case of cereal such as wheat and rye, the husks do not adhere to the kernel, also called caryopsis, and therefore their separation is carried out directly during the threshing. In case of cereals like rice, oat and spelt that have, instead, husks stuck to the kernel have to be semi-milled by two horizontal discs, so-called hullers, coated with abrasive material through which the kernel is decorticated removing the husks and the glumelle. The waste deriving from semi-milling for example from brown rice, i.e. from raw rice, after threshing, gives origin to the husks known also as rice hull, or rice chaff.

The cereal husks, and, in particular, the rice husks, have a high elasticity against bending of the hulls. More in detail, the cereal husks are substantially lens-shaped comprising concave portions and convex portions with rather high concavity. For these particular morphological features the cereal husks, and, in particular, the rice husks, occupy a high volume, but have a high void ratio. from which on the one hand a high elasticity derives and on the other hand a high draining action is achieved by the mixture that contains them.

The defibrated arboreus material which is resistant to microbial digestion can be, instead, a loose final product of raw material based on coir, or alternatively, a wood sawdust obtained from a raw material with high content of lignin, such as Teak sawdust, Mahogany sawdust, Iroko sawdust, or a combination thereof. In particular, the above described defibrated arboreus material which is resistant to microbial digestion, in the presence of moisture form a three-dimensional reticular structure that holds the lighter parts of infill material 10, in particular the cereal husks, “trapping them” and avoiding that they can get free from the turf infill and scatter in the environment. This makes it possible to exploit fully the physical characteristics of the cereal husks, in particular its high elasticity, and to avoid at the same time that it can hamper players during sports matches.

The infill material 10 can also comprise a predetermined amount of a loose final product from raw material based on ground cork. This way, mixing the ground cork to the cereal husks and to the defibrated arboreus material which is resistant to microbial digestion the physical characteristics of the infill material are further improved.

In an exemplary embodiment, the infill material 10 has a composition comprising between about 1% and about 15% v/v of cereal husks, between about 55% and 85% of raw material based on coconut ground and between about 20% and 35% of ground cork. The infill material 10 can comprise, furthermore, a predetermined amount of selected sand with controlled grain size, for example set between 0.4 mm and 2.0 mm.

In the exemplary embodiment shown in FIG. 2, the infill material 10 is made distributing a layer of sand 11 on face 2 b of mat 2 before laying layer 15 consisting of the above described mixture of loose material of vegetable natural origin.

In the exemplary embodiment of FIG. 3, the infill material 10 is obtained distributing in turn four layers of different material. In particular, a first layer 11 of sand and three layers 15 a-15 c, at least one of which consisting of a mixture of cereal husks with at least one defibrated arboreus material which is resistant to microbial digestion.

For example, above the layer 11 of sand a layer of cork 15 a is distributed, above which a layer of cereal husks 15 b is made mixed to a loose product based on coconut. Furthermore, a further layer 15 c can be provided comprising about exclusively a loose product based on coconut coir.

In the two exemplary embodiments above described the layer of sand 11 has draining function and is, furthermore, capable of adjusting the microclimate of the synthetic turf 1. The infill material 10 has, instead, mainly the function of adjusting the outflow and the drainage of the rainwater, or irrigation water, and to ensure a suitable rate of moisture of the playground.

As above described, the presence of the rice husks confers to the synthetic turf 1 appropriate physical and mechanical characteristics, necessary for the sports or recreational activities. The rice husks has, in fact, a high elasticity both if they are entire and fragmented. Furthermore, the rice husks ensure a correct drainage of water from the turf infill owing to a reduced water retention, allowing an adjustment of the outflow of water from the synthetic turf 1.

In a further exemplary embodiment shown in FIG. 4, the infill material 10′ provides a single heterogeneous layer consisting of a mixture of sand, cork, rice husks and loose product based on coconut ground in a determined percentage v/v. Even in this case the sand, even if mixed with the other components making up the infill material, carries out an effective draining action that avoids flooding the synthetic turf in case of strong rainfall.

As shown, for example in FIG. 3, the filaments 3 of synthetic material knitted on mat 2 can comprise at least one first group of longer filaments 3′, which protrude from the infill material 10 and at least one second group of filaments 3″, shorter, in order to result within the infill material 10 without protruding from it, or protruding minimally from it, for example 2-3 mm. This second group of filaments 3″ may have twisted shape in order to confer higher support to the infill material 10.

The following are not limitative examples of the components of the infill material, according to the invention:

1) Sand

-   -   Composition: siliceous sand and/or quartz with single, or         aggregate crystal quartz.     -   Minimum content of Si02: 70%     -   Physical state: solid     -   Form: crystalline     -   pH: 5÷8     -   Grain size: 0.4-0.9 mm     -   Density: 1500-1700 kg/m³

2) Organic Material of Vegetable Origin:

-   -   Composition: Vegetable natural material deriving from defibrated         arboreus plant parts, biodegradable, free from extraneous         material:     -   Form: irregular     -   Color: brown     -   Odor: odorless     -   Grain size: 1÷2 mm     -   pH: 5.0÷6.5     -   Electric conductivity: 0.63 uS/cm to 25° C.     -   moisture content: 5.0÷20.0%.

3) Rice Husks:

-   -   Composition: the husks or chaff of rice, or also hulls is the         waste deriving from the semi-milling of the brown rice, the raw         rice obtained after threshing. The ratio of the husks on the raw         rice changes according to the variety, and is set between 17 and         23 percent.     -   Colour: brown-beige,     -   Consistency: hard,     -   Density: 132÷140 kg/m³,     -   Features: imputrescible and not attackable by insects,     -   Composition:         -   proteins: 3.3%         -   fats: 1.1%         -   cellulose: 45%,         -   ashes: 17%,     -   average calorific value: 14 MJ/kg.

4) Loose Product of Raw Material Based on Coconut Coir:

-   -   Grain size: larger than 500 micron (□m) for 90% by weight,

Furthermore, hereafter a table is indicated of a standard composition of infill material, according to the invention.

Percent volume Component min max Loose product based on 55% 85% coconut coir Rice husks 1% 15% Ground cork 15% 35% Siliceous sand 0% 30%

In particular, the composition of the infill material given in the table can be adjusted within the range indicated responsive to the type of weaving and of density of the filaments (tufting), of the fibers used for making the synthetic turf, as well as responsive to the environmental features and of the ground that bears the turf, providing a customized distribution of the three components.

The infill material can be subject to changes concerning the succession of layers of the material, or the possible mixing of two, or all the components. For each specific case of stratification and succession, or mixing, of the material in any case is preferable to respect the percentage by weight of each element as indicated in the table 1 relative to a standard infill material standard.

Example

an infill for artificial soccer fields, comprising a layer of sand of about 8% v/v of siliceous sand and 92% of vegetable natural material.

The vegetable natural material comprises 6% rice husks, 22% ground cork and 72% coconut coir from which the powder part has been removed.

A similar composition, with about 6% of rice husks, about 22% ground cork and about 72% of coconut coir from which the powder part has been removed has been used successfully also with different proportions of sand from the above indicated range, and even without sand.

The foregoing description of a specific embodiment will so fully reveal the invention according to the conceptual point of view, so that others, by applying current knowledge, will be able to modify and/or adapt for various applications such an embodiment without further research and without parting from the invention, and it is therefore to be understood that such adaptations and modifications will have to be considered as equivalent to the specific embodiment. The means and the materials to realize the different functions described herein could have a different nature without, for this reason, departing from the field of the invention. It is to be understood that the phraseology or terminology employed herein is for the purpose of description and not of limitation. 

1. Infill material for synthetic turfs comprising a natural vegetable material that is at the same time imputrescible and not attackable by bacteria, wherein said natural vegetable material comprises a defibrated arboreus material which is resistant to microbial digestion in a percent volume set between 40% and 95%.
 2. Infill material for synthetic turfs according to claim 1 wherein said natural vegetable material comprises a defibrated arboreus material which is resistant to microbial digestion in a percent volume set between 65% and 85% v/v.
 3. Infill material for synthetic turfs according to claim 1 wherein said defibrated arboreus material comprises the defibrated arboreus material which is resistant to microbial digestion is obtained by sawdust wood obtained by a raw material with high content of lignin, selected from the group consisting of: Teak sawdust; Mahogany sawdust; Iroko sawdust; or a combination thereof.
 4. Infill material for synthetic turfs according to claim 1 comprising a mixture of: a measured amount of wood sawdust obtained from a raw material with high content of lignin, and; a measured amount of cereal husks.
 5. Infill material for synthetic turfs, according to claim 4, wherein said mixture furthermore comprises a measured amount of a loose product from raw material based on coconut coir.
 6. Infill material for synthetic turfs, according to claim 4, wherein said wood sawdust is obtained from the group comprised of: Teak sawdust; Mahogany sawdust; Iroko sawdust; or a combination thereof.
 7. Infill material for synthetic turfs, according to claim 4, wherein said cereal husks comprise selected from the group comprised of: rice husks; husks of wheat; husks of rye; husks of oat; husks of spelt; or a combination thereof.
 8. Infill material for synthetic turfs, according to claim 4, wherein said cereal husks comprise rice husks.
 9. Infill material for synthetic turfs, according to claim 1, wherein said cereal husks are present in said mixture in a percent volume set between 1% and 15%.
 10. Infill material for synthetic turfs, according to claim 1, wherein said cereal husks are present in said mixture in a percent volume set between 1% and 10%.
 11. Infill material for synthetic turfs, according to claim 1, wherein said mixture comprises, furthermore, a predetermined amount of a loose final product from raw material based on ground cork, in such a way that it is suitable for further improving the physical characteristics of said synthetic turf.
 12. Infill material for synthetic turfs, according to claim 1, wherein said mixture comprises, furthermore, a predetermined amount of sand.
 13. Infill material for synthetic turfs, according to claim 1, wherein said infill material comprises: a lower layer of sand; an upper layer consisting of said mixture.
 14. Infill material for synthetic turfs, according to claim 10, wherein said layer of sand is present in a volume set between 5% and 60% with respect to the total volume of said infill material.
 15. Infill material for synthetic turfs, according to claim 10 wherein said layer of sand is present in a volume set between 8% and 30% with respect to the total volume of the infill material.
 16. Infill material for synthetic turfs, according to claim 9, wherein said sand has a granulometry set between 0.4 mm and 2.0 mm.
 17. Infill material for synthetic turfs, according to claim 1, wherein the measured amount of wood sawdust is such that the percent volume of wood sawdust with respect to the total volume of the mixture is set between 40% and 95%.
 18. Infill material for synthetic turfs, according to claim 1, wherein the measured amount of wood sawdust in said mixture is such that the percent volume of wood sawdust with respect to the total volume of said mixture is set between 65% and 85%.
 19. Infill material for synthetic turfs, according to claim 1, wherein said mixture has the following composition: between about 1% to about 15% v/v of said cereal husks, in particular rice husks; between about 20% and about 35% v/v of cork; between about 55% and 80% of wood sawdust.
 20. Infill material for synthetic turfs, according to claim 1, wherein said mixture has the following composition: between about 1% and about 10% v/v of cereal husks, in particular rice husks; between about 20% and about 25% v/v of cork, in particular ground cork; between about 65% and 75% of wood sawdust.
 21. Infill material for synthetic turfs, according to claim 1, wherein said cereal husks have a moisture content set between 5% and 15%.
 22. Infill material for synthetic turfs, according to claim 2, wherein said loose final product from raw material based on coconut ground comprises the sole granular and fibrous part contained in the starting raw material based on coconut.
 23. Infill material for synthetic turfs, according to claim 19, wherein said granular and fibrous part contained in said loose product is obtained by sieving said raw material based on coconut coir.
 24. Infill material for synthetic turfs, according to claim 19, wherein said granular and fibrous part of coconut ground has a grain size larger than 500 micron (μm) for 90% by weight.
 25. Infill material for synthetic turfs, according to claim 19, wherein said granular and fibrous part has the following grain size: among 20% and 40% by weight set between 0.8 mm and 1.25 mm; among 15% and 35% by weight set between 1.25 mm and 1.60 mm; among 50% and 70% by weight larger than 1.6 mm.
 26. Infill material for synthetic turfs, according to claim 8, wherein said measured amount v/v of cork present in said mixture is set between 15% and 40% v/v.
 27. Infill material for synthetic turfs, according to claim 8, wherein said measured amount v/v of cork present in said mixture is set between 20% and 35% v/v.
 28. Synthetic turf for sports or recreational activities comprising: a mat equipped with a first face that is adapted to be arranged on a surface to coat and with a second face opposite to the first face; a plurality of filaments of synthetic material knitted on said mat, said plurality of filaments of synthetic material protruding from said second side in order to form a turf; an infill material for said turf; characterized in that said infill material comprises a loose material of vegetable origin, said loose material of vegetable origin being a mixture of: a measured amount of wood sawdust obtained from a raw material with high content of lignin; and; a measured amount of cereal husks.
 29. Synthetic turf, according to claim 25, wherein said filaments of synthetic material knitted on said mat comprises: a first group of longer filaments, said first group of filaments protruding from said infill material; a second group of shorter filaments, said second group of filaments arranged within the infill material without protruding from it, or protruding minimally from it.
 30. Synthetic turf, according to claim 26, wherein said filaments of said second group of filaments has a twisted shape in order to give higher support to the infill material.
 31. A method for making a synthetic turf comprising the steps of: preparing a turf comprising a mat to which a plurality of filaments of synthetic material is connected, said mat equipped with a first face that is adapted to be arranged on a surface to coat and with a second face opposite to the first face, said plurality of filaments of synthetic material protruding from said second face; laying on said first face of said mat an infill material obtaining a synthetic turf; characterized in that said infill material comprises a loose material of vegetable origin, said loose material of vegetable origin being a mixture of: a measured amount of wood sawdust obtained from a raw material with high content of lignin; a measured amount of cereal husks.
 32. Method for making a synthetic turf, according to claim 28, wherein said step of distributing said infill material comprises the steps of: distributing a layer of sand on said mat; distributing a layer consisting of said mixture on said layer of sand. 